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Personne :
Beaulieu, Jean Martin

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Beaulieu

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Jean Martin

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Université Laval. Département de psychiatrie et de neurosciences

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ncf11860295

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  • PublicationRestreint
    A dense cluster of D1+ cells in the mouse nucleus accumbens
    (2017-01-01) Gagnon, Dave; Beaulieu, Jean Martin; Sánchez, Maria Gabriela; Parent, Martin; Petryszyn, Sarah; Parent, André
    The striatum is known to be largely composed of intermingled medium-sized projection neurons expressing either the D1 or the D2 dopamine receptors. In the present study, we took advantage of the double BAC Drd1a-TdTomato/Drd2-GFP (D1 /D2 ) transgenic mice to reveal the presence of a peculiar cluster of densely-packed D1 + cells located in the shell compartment of the nucleus accumbens. This spherical cluster has a diameter of 110 µm and is exclusively composed by D1 + cells, which are all immunoreactive for the neuronal nuclear marker (NeuN). However, in contrast to other D1 + or D2 + striatal cells, those that form the accumbens cluster are devoid of calbindin (CB) and DARPP-32, two faithful markers for striatal projection neurons. Using GAD-GFP transgenic mice, we confirm the GABAergic nature of the D1 + clustered neurons. Intracellular injections from fixed brain slices indicate that these neurons are endowed with distinctive morphological features, including a small (5-6 µm), round cell body giving rise to a single primary dendrite that branches into two secondary processes. Single-neuronal injections combined to electron microscopy reveal the existence of GAP junctions linking these D1 + cells. Based on their location, morphological characteristics and neurochemical phenotype, we conclude that the D1 + accumbens cluster form a highly compact group of small neurons distinct from the larger and more diffusely distributed D1 + or D2 + striatal projection neurons that surround it. This remarkable nucleus might play a crucial role in the limbic function of the murine striatum.
  • PublicationRestreint
    Distribution and morphological characteristics of striatal interneurons expressing calretinin in mice : a comparison with human and nonhuman primates
    (2014-06-21) Beaulieu, Jean Martin; Parent, Martin; Petryszyn, Sarah; Parent, André
    Striatal interneurons display a morphological and chemical heterogeneity that has been particularly well characterized in rats, monkeys and humans. By comparison much less is known of striatal interneurons in mice, although these animals are now widely used as transgenic models of various neurodegenerative diseases. The present immunohistochemical study aimed at characterizing striatal interneurons expressing calretinin (CR) in mice compared to those in squirrel monkeys and humans. The mouse striatum contains both small (9-12 μm) and medium-sized (15-20 μm) CR+ cells. The small cells are intensely stained with a single, slightly varicose and moderately arborized process. They occur throughout the striatum (77±9 cells/mm(3)), but prevail in the area of the subventricular zone and subcallosal streak, with statistically significant anteroposterior and dorsoventral decreasing gradients. The medium-sized cells are less intensely immunoreactive and possess 2-3 long, slightly varicose and poorly branched dendrites. They are rather uniformly scattered throughout the striatum and three times more numerous (224±31 cells/mm(3)) than the smaller CR+ cells. Double immunostaining experiments with choline acetyltransferase (ChAT) as a cholinergic marker in normal and Drd1a-tdTomato/Drd2-EGFP double transgenic mice reveal that none of the small or medium-sized CR+ cells express ChAT or D1 and D2 dopamine receptors. In contrast, the striatum in human and nonhuman primates harbors small and medium-sized CR+/ChAT- cells, as well as large CR+/ChAT+ interneurons that are absent in mice. Such a difference between rodents and primates must be taken into consideration if one hopes to better understand the striatal function in normal and pathological conditions.